Roles of the Werner syndrome RecQ helicase in DNA replication

Congenital deficiency in the WRN protein, a member of the human RecQ helicase family, gives rise to Werner syndrome, a genetic instability and cancer predisposition disorder with features of premature aging. Cellular roles of WRN are not fully elucidated. WRN has been implicated in telomere maintenance, homologous recombination, DNA repair, and other processes. Here I review the available data that directly address the role of WRN in preserving DNA integrity during replication and propose that WRN can function in coordinating replication fork progression with replication stress-induced fork remodeling. I further discuss this role of WRN within the contexts of damage tolerance group of regulatory pathways, and redundancy and cooperation with other RecQ helicases.     

Mechanism and substrate specificity of telomeric protein POT1 stimulation of the Werner syndrome helicase

Loss of the RecQ helicase WRN protein causes the cancer-prone progeroid disorder Werner syndrome (WS). WS cells exhibit defects in DNA replication and telomere preservation. The telomeric single-stranded binding protein POT1 stimulates WRN helicase to unwind longer telomeric duplexes that are otherwise poorly unwound. We reasoned that stimulation might occur by POT1 recruiting and retaining WRN on telomeric substrates during unwinding and/or by POT1 loading on partially unwound ssDNA strands to prevent strand re-annealing. To test these possibilities, we used substrates with POT1-binding sequences in the single-stranded tail, duplex or both. POT1 binding to ssDNA tails did not alter WRN activity on nontelomeric duplexes or recruit WRN to telomeric ssDNA. However, POT1 bound tails inhibited WRN activity on telomeric duplexes with a single 3'-ssDNA tail, which mimic telomeric ends in the open conformation. In contrast, POT1 bound tails stimulated WRN unwinding of forked telomeric duplexes. This indicates that POT1 interaction with the ssDNA/dsDNA junction regulates WRN activity. Furthermore, POT1 did not enhance retention of WRN on telomeric forks during unwinding. Collectively, these data suggest POT1 promotes the apparent processivity of WRN helicase by maintaining partially unwound strands in a melted state, rather than preventing WRN dissociation from the substrate.     

Biochemical characterization of the DNA substrate specificity of Werner syndrome helicase

Werner syndrome is a hereditary premature aging disorder characterized by genome instability. The product of the gene defective in WS, WRN, is a helicase/exonuclease that presumably functions in DNA metabolism. To understand the DNA structures WRN acts upon in vivo, we examined its substrate preferences for unwinding. WRN unwound a 3'-single-stranded (ss)DNA-tailed duplex substrate with streptavidin bound to the end of the 3'-ssDNA tail, suggesting that WRN does not require a free DNA end to unwind the duplex; however, WRN was completely blocked by streptavidin bound to the 3'-ssDNA tail 6 nucleotides upstream of the single-stranded/double-stranded DNA junction. WRN efficiently unwound the forked duplex with streptavidin bound just upstream of the junction, suggesting that WRN recognizes elements of the fork structure to initiate unwinding. WRN unwound two important intermediates of replication/repair, a 5'-ssDNA flap substrate and a synthetic replication fork. WRN was able to translocate on the lagging strand of the synthetic replication fork to unwind duplex ahead of the fork. For the 5'-flap structure, WRN specifically displaced the 5'-flap oligonucleotide, suggesting a role of WRN in Okazaki fragment processing. The ability of WRN to target DNA replication/repair intermediates may be relevant to its role in genome stability maintenance.     

Inhibition of Werner syndrome helicase activity by benzo[a]pyrene diol epoxide adducts can be overcome by replication protein A

RecQ helicases are believed to function in repairing replication forks stalled by DNA damage and may also play a role in the intra-S-phase checkpoint, which delays the replication of damaged DNA, thus permitting repair to occur. Since little is known regarding the effects of DNA damage on RecQ helicases, and because the replication and recombination defects in Werner syndrome cells may reflect abnormal processing of damaged DNA associated with the replication fork, we examined the effects of specific bulky, covalent adducts at N(6) of deoxyadenosine (dA) or N(2) of deoxyguanosine (dG) on Werner (WRN) syndrome helicase activity. The adducts are derived from the optically active 7,8-diol 9,10-epoxide (DE) metabolites of the carcinogen benzo[a]pyrene (BaP). The results demonstrate that WRN helicase activity is inhibited in a strand-specific manner by BaP DE-dG adducts only when on the translocating strand. These adducts either occupy the minor groove without significant perturbation of DNA structure (trans adducts) or cause base displacement at the adduct site (cis adducts). In contrast, helicase activity is only mildly affected by intercalating BaP DE-dA adducts that locally perturb DNA double helical structure. This differs from our previous observation that intercalating dA adducts derived from benzo[c]phenanthrene (BcPh) DEs inhibit WRN activity in a strand- and stereospecific manner. Partial unwinding of the DNA helix at BaP DE-dA adduct sites may make such adducted DNAs more susceptible to the action of helicase than DNA containing the corresponding BcPh DE-dA adducts, which cause little or no destabilization of duplex DNA. The single-stranded DNA binding protein RPA, an auxiliary factor for WRN helicase, enabled the DNA unwinding enzyme to overcome inhibition by either the trans-R or cis-R BaP DE-dG adduct, suggesting that WRN and RPA may function together to unwind duplex DNA harboring specific covalent adducts that otherwise block WRN helicase acting alone.     

The Werner syndrome protein stimulates DNA polymerase beta strand displacement synthesis via its helicase activity

Werner syndrome is a hereditary premature aging disorder characterized by genomic instability. Genetic analysis and protein interaction studies indicate that the defective gene product (WRN) may play an important role in DNA replication, recombination, and repair. DNA polymerase beta (pol beta) is a central participant in both short and long-patch base excision repair (BER) pathways, which function to process most spontaneous, alkylated, and oxidative DNA damage. We report here a physical interaction between WRN and pol beta, and using purified proteins reconstitute of a portion of the long-patch BER pathway to examine a potential role for WRN in this repair response. We demonstrate that WRN stimulates pol beta strand displacement DNA synthesis and that this stimulation is dependent on the helicase activity of WRN. In addition, a truncated WRN protein, containing primarily the helicase domain, retains helicase activity and is sufficient to mediate the stimulation of pol beta. The WRN helicase also unwinds a BER substrate, providing evidence that WRN plays a role in unwinding DNA repair intermediates. Based on these findings, we propose a novel mechanism by which WRN may mediate pol beta-directed long-patch BER.     

DNA damage induced hyperphosphorylation of replication protein A. 2. Characterization of DNA binding activity, protein interactions, and activity in DNA replication and repair

Replication protein A (RPA) is a heterotrimeric protein consisting of 70-, 34-, and 14- kDa subunits that is required for many DNA metabolic processes including DNA replication and DNA repair. Using a purified hyperphosphorylated form of RPA protein prepared in vitro, we have addressed the effects of hyperphosphorylation on steady-state and pre-steady-state DNA binding activity, the ability to support DNA repair and replication reactions, and the effect on the interaction with partner proteins. Equilibrium DNA binding activity measured by fluorescence polarization reveals no difference in ssDNA binding to pyrimidine-rich DNA sequences. However, RPA hyperphosphorylation results in a decreased affinity for purine-rich ssDNA and duplex DNA substrates. Pre-steady-state kinetic analysis is consistent with the equilibrium DNA binding and demonstrates a contribution from both the k(on) and k(off) to achieve these differences. The hyperphosphorylated form of RPA retains damage-specific DNA binding, and, importantly, the affinity of hyperphosphorylated RPA for damaged duplex DNA is 3-fold greater than the affinity of unmodified RPA for undamaged duplex DNA. The ability of hyperphosphorylated RPA to support DNA repair showed minor differences in the ability to support nucleotide excision repair (NER). Interestingly, under reaction conditions in which RPA is maintained in a hyperphosphorylated form, we also observed inhibition of in vitro DNA replication. Analyses of protein-protein interactions bear out the effects of hyperphosphorylated RPA on DNA metabolic pathways. Specifically, phosphorylation of RPA disrupts the interaction with DNA polymerase alpha but has no significant effect on the interaction with XPA. These results demonstrate that the effects of DNA damage induced hyperphosphorylation of RPA on DNA replication and DNA repair are mediated through alterations in DNA binding activity and protein-protein interactions.     

Telomere repeat DNA forms a large non-covalent complex with unique cohesive properties which is dissociated by Werner syndrome DNA helicase in the presence of replication protein A

We describe the unique structural features of a large telomere repeat DNA complex (TRDC) of >20 kb generated by a simple PCR using (TTAGGG)₄ and (CCCTAA)₄ as both primers and templates. Although large, as determined by conventional agarose gel electrophoresis, the TRDC was found to consist of short single-stranded DNA telomere repeat units of between several hundred and 3000 bases, indicating that it is a non-covalent complex comprising short cohesive telomere repeat units. S1 nuclease digestion showed that the TRDC contains both single- and double-stranded portions stable enough to survive glycerol density gradient centrifugation, precipitation with ethanol and gel electrophoresis. Sedimentation analysis suggests that a part of the TRDC is non-linear and consists of a three-dimensional network structure. After treatment with Werner DNA helicase the TRDC dissociated into smaller fragments, provided that human replication protein A was present, indicating that: (i) the TRDC is a new substrate for the Werner syndrome helicase; (ii) the telomere repeat sequence re-anneals rapidly unless unwound single-stranded regions are protected by replication protein A; (iii) the TRDC may provide a new clue to understanding deleterious telomere–totelomere interactions that can lead to genomic instability. Some properties of the TRDC account for the extra-chromosomal telomere repeat (ECTR) DNA that exists in telomerase-negative immortalized cell lines and may be involved in maintaining telomeres.     

Calf thymus DNA helicase F, a replication protein A copurifying enzyme.

A DNA helicase from calf thymus, called DNA helicase F, copurified with replication protein A through several steps of purification including DEAE-Sephacel, hydroxyapatite and single stranded DNA cellulose. It is finally separated from replication protein A on FPLC Mono Q where the DNA helicase elutes after replication protein A. Characterization of the DNA helicase F by affinity labeling with [alpha 32P]ATP indicated that the enzyme has a catalytic subunit of 72 kDa. Gel filtration experiments suggested that DNA helicase F can exist both in a monomeric and an oligomeric form. The enzyme unwinds DNA in the 5'-->3' direction in relation to the strand it binds. All eight deoxyribonucleoside- and ribonucleosidetriphosphates could serve as an energy source. Testing a variety of DNA/DNA substrates demonstrated that the DNA helicase F preferentially unwinds very short substrates and is slightly stimulated by a single stranded 3'-tail. However, replication protein A allowed the DNA helicase to unwind much longer DNA substrates of up to 400 bases, indicating that the copurification of replication protein A with the DNA helicase F might be of functional relevance.     

Characterization of the DNA-unwinding activity of human RECQ1, a helicase specifically stimulated by human replication protein A

The RecQ helicases are involved in several aspects of DNA metabolism. Five members of the RecQ family have been found in humans, but only two of them have been carefully characterized, BLM and WRN. In this work, we describe the enzymatic characterization of RECQ1. The helicase has 3' to 5' polarity, cannot start the unwinding from a blunt-ended terminus, and needs a 3'-single-stranded DNA tail longer than 10 nucleotides to open the substrate. However, it was also able to unwind a blunt-ended duplex DNA with a "bubble" of 25 nucleotides in the middle, as previously observed for WRN and BLM. We show that only short DNA duplexes (<30 bp) can be unwound by RECQ1 alone, but the addition of human replication protein A (hRPA) increases the processivity of the enzyme (>100 bp). Our studies done with Escherichia coli single-strand binding protein (SSB) indicate that the helicase activity of RECQ1 is specifically stimulated by hRPA. This finding suggests that RECQ1 and hRPA may interact also in vivo and function together in DNA metabolism. Comparison of the present results with previous studies on WRN and BLM provides novel insight into the role of the N- and C-terminal domains of these helicases in determining their substrate specificity and in their interaction with hRPA.     

DNA unwinding activity of replication protein A.

Replication protein A (RP-A) is a heterotrimeric complex conserved in eukaryotic cells. It binds to single-stranded DNA and is essential for initiation and elongation of DNA replication. In this communication we give evidence that this protein can unwind DNA independent of magnesium and ATP, two essential cofactors for bona fide DNA helicase activity. RP-A can unwind up to at least 350 basepairs and appears to be required in stoichiometric amounts. The reaction is extremely sensitive to NaCl and MgCl2. This activity of RF-A is suggestive for a possible unwinding function in initiation of DNA replication in eukaryotes.     

Molecular cooperation between the Werner syndrome protein and replication protein A in relation to replication fork blockage

The premature aging and cancer-prone disease Werner syndrome is caused by loss of function of the RecQ helicase family member Werner syndrome protein (WRN). At the cellular level, loss of WRN results in replication abnormalities and chromosomal aberrations, indicating that WRN plays a role in maintenance of genome stability. Consistent with this notion, WRN possesses annealing, exonuclease, and ATPase-dependent helicase activity on DNA substrates, with particularly high affinity for and activity on replication and recombination structures. After certain DNA-damaging treatments, WRN is recruited to sites of blocked replication and co-localizes with the human single-stranded DNA-binding protein replication protein A (RPA). In this study we examined the physical and functional interaction between WRN and RPA specifically in relation to replication fork blockage. Co-immunoprecipitation experiments demonstrated that damaging treatments that block DNA replication substantially increased association between WRN and RPA in vivo, and a direct interaction between purified WRN and RPA was confirmed. Furthermore, we examined the combined action of RPA (unmodified and hyperphosphorylation mimetic) and WRN on model replication fork and gapped duplex substrates designed to bind RPA. Even with RPA bound stoichiometrically to this gap, WRN efficiently catalyzed regression of the fork substrate. Further analysis showed that RPA could be displaced from both substrates by WRN. RPA displacement by WRN was independent of its ATPase- and helicase-dependent remodeling of the fork. Taken together, our results suggest that, upon replication blockage, WRN and RPA functionally interact and cooperate to help properly resolve replication forks and maintain genome stability.     

Simian virus 40 large T antigen DNA helicase. Characterization of the ATPase-dependent DNA unwinding activity and its substrate requirements

The ATPase of SV40 large T antigen (T antigen) which is essential for the replication of SV40 minichromosomes was recently shown to be functionally related to a newly discovered DNA helicase activity. The T antigen helicase unwinds DNA duplices of several kilobase pairs in a reaction depending on the presence of hydrolyzable ribo- or deoxyribonucleoside triphosphates. The in vitro rate of movement through duplex DNA was found to be about 100 base pairs/min at 37 degrees C. For DNA unwinding, T antigen requires a 3'-single strand extension of a partially double-stranded substrate and invades the double strand section processively, in a 3' to 5' direction. The minimum length of the single-stranded tail was determined to be less than 5 nucleotides. Unwinding studies in the presence of the Escherichia coli single strand-specific DNA-binding protein and competition experiments indicate that T antigen helicase binds preferentially at the single-stranded/double-stranded DNA junction. This DNA structure is therefore proposed to serve as an entry site for the T antigen helicase. Previously reported data suggest that T antigen is the replicative helicase of the SV40 minichromosome. The results presented here are consistent with these findings and imply that T antigen migrates actively and processively along the template for the leading strand.     

Displacement of DNA-PKcs from DNA ends by the Werner syndrome protein

The DNA-dependent protein kinase (DNA-PK) complex, which is composed of a DNA-dependent kinase subunit (DNA-PKcs) and the Ku70/80 heterodimer, is involved in DNA double-strand break repair by non-homologous end joining (NHEJ). Ku70/80 interacts with the Werner syndrome protein (WRN) and stimulates WRN exonuclease activity. To investigate a possible function of WRN in NHEJ, we have examined the relationship between DNA-PKcs, Ku and WRN. First, we showed that WRN forms a complex with DNA-PKcs and Ku in solution. Next, we determined whether this complex assembles on DNA ends. Interestingly, the addition of WRN to a Ku:DNA-PKcs:DNA complex results in the displacement of DNA-PKcs from the DNA, indicating that the triple complex WRN:Ku:DNA-PKcs cannot form on DNA ends. The displacement of DNA-PKcs from DNA requires the N- and C-terminal regions of WRN, both of which make direct contact with the Ku70/80 heterodimer. Moreover, exonuclease assays indicate that DNA-PKcs does not protect DNA from the nucleolytic action of WRN. These results suggest that WRN may influence the mechanism by which DNA ends are processed.     

DNA damage-induced translocation of the Werner helicase is regulated by acetylation

Werner syndrome is a rare autosomal recessive disorder involving the premature appearance of features reminiscent of human aging. Werner syndrome occurs by mutation of the WRN gene, encoding a DNA helicase. WRN contributes to the induction of the p53 tumor suppressor protein by various DNA damaging agents. Here we show that UV exposure leads to extensive translocation of WRN from the nucleolus to nucleoplasmic foci in a dose-dependent manner. Ionizing radiation also induces WRN translocation, albeit milder, partially through activation of the ATM kinase. The nucleoplasmic foci to which WRN is recruited display partial colocalization with PML nuclear bodies. The translocation of WRN into nucleoplasmic foci is significantly enhanced by the protein deacetylase inhibitor, Trichostatin A. Moreover, Trichostatin A delays the re-entry of WRN into the nucleolus at late times after irradiation. WRN is acetylated in vivo, and this is markedly stimulated by the acetyltransferase p300. Importantly, p300 augments the translocation of WRN into nucleoplasmic foci. These findings support the notion that WRN plays a role in the cellular response to DNA damage and suggest that the activity of WRN is modulated by DNA damage-induced post-translational modifications of WRN and possibly WRN-interacting proteins.     

The Werner syndrome protein contributes to induction of p53 by DNA damage.

Mutations in the p53 tumor-suppressor gene promote increased genomic instability and cancer. Mutations in the WRN gene, encoding a DNA helicase, underlie the segmental progeroid Werner syndrome (WS). WS is also associated with increased genomic instability and elevated cancer risk. The p53 and WRN proteins can engage in direct protein-protein interactions. We report that excess WRN elicits increased cellular p53 levels and potentiates p53-mediated apoptosis. Importantly, cells derived from WS patients exhibit an attenuated and delayed induction of p53 by UV or by the topoisomerase I inhibitor camptothecin. These results suggest that WRN may participate in the activation of p53 in response to certain types of DNA damage. Furthermore, the failure to induce p53 effectively may contribute to enhanced genomic instability and elevated cancer risk in WS patients.     

A DNA helicase purified by replication protein A (RPA) affinity chromatography from mouse FM3A cells.

In an effort to identify cellular helicases that mimic the action of SV40 large T-antigen, we performed replication protein A (RPA) affinity chromatography on cell extracts from the mouse mammary carcinoma cell line FM3A. In this way, a novel DNA helicase was isolated and purified to near homogeneity. The most purified fractions showed the presence of two proteins of 28 and 21 kDa. Both proteins interacted with 32P-labeled partially duplex DNA when bound to nitrocellulose membranes and were efficiently UV crosslinked to [alpha-32P]dATP. Helicase activity was strongly stimulated by RPA on DNA substrates containing duplex regions longer than 18 bp. Only weak stimulation was observed in the presence of Escherichia coli single strand DNA binding protein (SSB). The enzyme unwinds DNA in the 5'-3' direction in relation to the strand to which it binds. Only ATP and dATP were efficient as nucleoside triphosphate co-factors, and showed similar Km values of approximately 0.6 mM. The properties of this enzyme suggest that it may take part in reactions mediated by RPA such as those predicted to occur at replication forks or alternatively may function during DNA repair or recombination.     

p53 Modulates the exonuclease activity of Werner syndrome protein.

Werner syndrome (WS) is characterized by the early onset of symptoms of premature aging, cancer, and genomic instability. The molecular basis of the defects is not understood but presumably relates to the DNA helicase and exonuclease activities of the protein encoded by the WRN gene that is mutated in the disease. The attenuation of p53-mediated apoptosis in WS cells and reported physical interaction between WRN and the tumor suppressor p53 suggest that p53 and WRN functionally interact in a pathway necessary for the normal cellular response. In this study, we have demonstrated that p53 inhibits the exonuclease activity of the purified full-length recombinant WRN protein. p53 did not have an effect on a truncated amino-terminal WRN fragment that retains exonuclease activity but lacks the physical interaction domain for p53 located in the carboxyl terminus. Two naturally occurring p53 mutants found in human cancer displayed a reduced ability to inhibit WRN exonuclease activity. In cells arrested in S phase with hydroxyurea, WRN exits the nucleolus and colocalizes with p53 in the nucleoplasm. The regulation of WRN function by p53 is likely to play an important role in the maintenance of genomic integrity and prevention of cancer and other clinical symptoms associated with WS.     

Binding activity of replication protein A to UV-damaged single-stranded DNA.

To obtain the information for the exact role of replication protein A (RPA) on both eukaryotic DNA replication and repair, the binding preference of RPA purified from Xenopus egg extract against the undamaged and UV-damaged single-stranded DNA was studied by the gel shift assay. Chemically synthesized oligonucleotide containing the pyrimidine(6-4)pyrimidone photoproduct at one site was used as a model of UV-damaged DNA. Results of competition assay and Scatchard plots indicate that RPA preferentially binds to the 6-4 photoproduct oligonucleotide than the undamaged DNA.